CN111103187B - Method for predicting breaking impact strength of key layers at different layers - Google Patents
Method for predicting breaking impact strength of key layers at different layers Download PDFInfo
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- CN111103187B CN111103187B CN201911229798.6A CN201911229798A CN111103187B CN 111103187 B CN111103187 B CN 111103187B CN 201911229798 A CN201911229798 A CN 201911229798A CN 111103187 B CN111103187 B CN 111103187B
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N3/00—Investigating strength properties of solid materials by application of mechanical stress
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- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2203/00—Investigating strength properties of solid materials by application of mechanical stress
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- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2203/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N2203/0014—Type of force applied
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- G01N2203/0019—Compressive
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- G—PHYSICS
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- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
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- G01N2203/006—Crack, flaws, fracture or rupture
- G01N2203/0067—Fracture or rupture
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- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
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- G01N2203/0069—Fatigue, creep, strain-stress relations or elastic constants
- G01N2203/0075—Strain-stress relations or elastic constants
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- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2203/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N2203/02—Details not specific for a particular testing method
- G01N2203/06—Indicating or recording means; Sensing means
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Abstract
The invention relates to a method for monitoring breaking strength of an overlying strata after coal seam mining, in particular to a method for predicting breaking impact strength of key layers at different layers. The method solves the problem of prediction of rock stratum breaking motion strength after coal seam mining, tests coal rock physical mechanical parameters through ground drilling coring, lays a physical similar model in a reasonable proportion, arranges a stress monitor, monitors the advanced coal body loaded stress strength when key layers of different layers break, compares the advanced coal body loaded stress strength with the coal body compressive strength, and analyzes the impact strength of the key layer break. The prediction method is simple and easy to implement, has reliable results, and has important guiding significance for predicting the safety of coal seam mining and pertinently providing a control technical means.
Description
Technical Field
The invention relates to a method for monitoring breaking strength of an overlying strata after coal seam mining, in particular to a method for predicting breaking impact strength of key layers at different layers.
Background
In the process of underground coal seam mining, the movement and control of an overlying rock stratum are one of the core problems of coal mining all the time, and the movement of the rock stratum has certain influence on the problems of surrounding rock deformation, water permeability, gas outburst, support, extraction and the like, and is a core incentive for coal mine disasters. Especially for hard roof mining areas, the fracture instability of a hard roof covered on a coal seam is a core factor causing the strong mine pressure of a working face to appear, but due to the complexity of underground space, rock stratum movement is always in the field of a 'dark box', accurate detection cannot be realized, and the current prevention and control on disasters such as stope mine pressure and the like are still in the passive defense stage. Therefore, the method solves the problem of predicting the breaking impact strength of the overlying key layer, and has great significance for improving the safety of mine exploitation, guiding the design of mine exploitation support and the like.
Disclosure of Invention
The invention provides a method for predicting breaking impact strength of key layers of different layers, aiming at solving the problem of predicting rock stratum breaking movement strength after coal seam mining.
The invention adopts the following technical scheme: a method for predicting breaking impact strength of key layers at different layers comprises the following steps.
S100, before mining on the underground working face of the mine, vertically drilling a borehole television observation hole downwards from the ground surface along the advancing direction of the working face, observing the overlying strata structure and lithology of the working face through a borehole television, measuring, calculating and recording the thickness, the occurrence and the lithology of each coal-rock layer.
S200, randomly taking the coal rock core of one of the borehole television observation holes to test the mechanical property of the coal rock stratum, measuring and calculating the compressive strength, the tensile strength, the compressive strength, the volume weight, the thickness, the elastic modulus and the Poisson ratio of the coal rock stratum, and calculating to obtain the key layer position of the overlying rock stratum of the working surface through a key layer theory according to the measured mechanical parameters of the coal rock stratum.
S300, manufacturing a physical similar model, setting a similar proportion, calculating according to the similar proportion to obtain a matching number for manufacturing each coal rock layer, matching manufacturing materials according to the matching number, and paving the model.
S400-when the model is laid, the distance is separated at the interface of the coal bed and the direct roofDLaying a strain gauge, loading strength P on the strain gauge before laying the strain gauge, measuring strain change epsilon of the strain gauge, and measuring and calculating the elastic modulus of the strain gauge according to the formula E = P/epsilonE。
S500-set the width on both sides of the model asLAccording to the similar proportion, the model excavation speed is calculated and obtainedvAnd excavating the working surface of the model at the speed.
S600, mining along with the working face of the model, recording data changes of the working face advanced strain gauge when the key layer covering different layers is broken, and combining the elastic modulus of the strain gaugeEAnd calculating to obtain the working surface lead stress data sigma.
S700-taking the leading stress sigma closest to the working face and the compressive strength of the coal bodyRComparing:
if sigma is more than or equal to 2RThe breaking impact strength of the key layer is considered to be extremely high;
if it isR≤ σ <2RThe breaking impact strength of the key layer is considered to be higher;
if 0.5R≤σ<RThe breaking impact strength of the key layer is considered to be general;
if σ is less than 0.5RThe critical layer rupture impact strength is considered to be weaker.
S800, after the working face is mined on the spot, stress measuring points are arranged in a coal seam in the advanced roadway range of the working face at intervals of 10-15 m, and stress data sigma of the measuring points when different key layers of the overburden rock are broken is monitored0。
S900, sequentially comparing the stress sigma and the stress sigma of the coal body at the position closest to the working face when the same key layer is broken and obtained by a physical simulation test and field actual measurement0Remember ki=σ0σ, where i is the key layer horizon, and kiTake the average value, mark as ki′。
S1000-when the next working face is mined, the same steps are adopted to lay a physical model, and the stress of the advanced coal body is sigma' when the key layer is broken is monitored and obtained, and the stress is recorded as sigma = ki'Sigma' to increase the compression strength of the coal bodyRAnd comparing the relative ratio, and judging the breaking impact strength of the key layer.
Further, the distance between the strain gauges is setDAnd face mining speed in the modelvThe relationship of (1) is D = (0.5 to 0.8)v。
Further, the width of the model is reserved at two sidesLThe relationship between the protective coal pillar and the model laying length is L = (0.1-0.2) × the model laying length.
Compared with the prior art, the invention has the following beneficial effects:
1) the roof breaking strength is predicted by adopting a physical similarity simulation method, and the method is simple, reliable and easy to implement;
2) by adopting a method combining laboratory tests and field actual measurement, test results can be verified, test results are fed back and optimized, and the accuracy of prediction results is further improved;
3) the roof breaking strength is predicted by applying the patent method, and a prediction result can provide theoretical guidance for roof control and has practical significance;
4) the hard roof mining area of China accounts for one third of the mining area of China, the hard roof breaking strength prediction method is simple in operation flow and reliable in result, has theoretical guiding significance for safe and efficient mining of the hard roof mining area of China, and is wide in prospect.
Drawings
FIG. 1 is a schematic diagram of the present invention;
FIG. 2 is a schematic view of a physical model;
in the figure, 1 — model; 2-coal bed; 3-direct jacking; 4-a strain gauge; 5, protecting the coal pillars; 6-working surface of model; 7-Key layer.
Detailed Description
A method for predicting breaking impact strength of key layers at different layers is characterized in that a mining area of an extra-thick coal seam with a hard roof and 20m of the extra-thick coal seam are used as engineering background to predict the breaking impact strength of the key layers at different layers covered on the mining area.
S100, before mining on the underground working face of the mine, vertically drilling a borehole television observation hole downwards from the ground surface along the advancing direction of the working face, observing the overlying strata structure and lithology of the working face through a borehole television, measuring, calculating and recording the thickness, the occurrence and the lithology of each coal-rock layer.
S200, randomly taking a coal rock core of one of the borehole television observation holes to test the mechanical properties of the coal rock stratum, mainly measuring and calculating the compressive strength, the tensile strength, the compressive strength, the volume weight, the thickness, the elastic modulus and the Poisson ratio of the coal rock stratum, calculating to obtain the key layer position of the overlying rock stratum of the working surface according to the measured mechanical parameters of the coal rock stratum through a key layer theory, and calculating to obtain the positions of the overlying multi-layer key layer of the working surface, which are respectively 17, 45, 75, 107 and 146m away from the coal bed.
S300, manufacturing a physical similar model 1, wherein the length and width of the model frame are 2.5M 2M, the length of the model 1 is consistent with the length of the model frame, the similar ratio is set to be 1:150, the motion time similarity ratio of the model 1 is calculated to be 12.25:1 and the stress similarity ratio is 250:1 according to the design principle of the similar model, the matching number for manufacturing each coal stratum is calculated according to the similar ratio, the materials are manufactured according to the matching number, the model 1 is laid, taking the first key layer 7 as an example, the compressive strength of the model 1 is measured to be 55.53MPa in a laboratory, the simulation strength is 222.12KPa according to the stress similarity ratio, the corresponding matching number is obtained by table look-up and is 437, the matching is carried out by taking sand, calcium carbonate and gypsum as raw materials, the usage amount of the sand is 4/5 (the mass of the whole rock stratum), the mass of the calcium carbonate is 1/5 3/10, the amount of gypsum was M1/5 3/7 and the amount of water was M1/9.
S400-when the model 1 is laid, strain gauges 4 are laid at the interface of the coal seam 2 and the direct roof 3 at intervals of 5cm, a certain strength of 32N is loaded on the strain gauges 4 before the strain gauges 4 are laid, and meanwhile, the strain change of the strain gauges 4 is measured to be 230 x 10-3E, calculating the elastic modulus of the strain gauge 4 according to the formula E = P/EEIs 0.11 GPa.
S500-reserving 40cm protective coal pillars 5 on two sides of the model, obtaining a movement time similarity ratio of 12.25:1 according to a similarity ratio, obtaining a coal mining working time of 16 hours on an actual working face, a maintenance working time of 8 hours, and a footage of about 4m each day, and calculating the working time and excavation distance of the working face of the model to obtain,h=78min,. The excavation speed of the model 1 is calculated, namely 2.67cm is excavated every 78min, and the model working face 6 is excavated at the speed.
S600 mining along with the model working face 6, recording the data change of the working face advanced strain gauge 4 when the key layer 7 covering different layers is broken, and combining the elastic modulus of the strain gauge 4EAnd calculating to obtain the advanced stress data sigma of the working surface 4.
S700-taking the leading stress sigma closest to the working surface 6 and the compressive strength of the coal bodyRComparing:
if sigma is more than or equal to 2RThe breaking impact strength of the key layer is considered to be extremely high;
if it isR≤ σ <2RThen consider the key layerThe breaking impact strength is higher;
if 0.5R≤σ<RThe breaking impact strength of the key layer is considered to be general;
if σ is less than 0.5RThe critical layer rupture impact strength is considered to be weaker.
S800, after the working face is mined on the spot, stress measuring points are arranged in the coal seam in the advanced roadway range of the working face at intervals of 10 m, and stress data sigma of the measuring points when different key layers of the overburden rock are broken is monitored0。
S900, sequentially comparing the stress sigma and the stress sigma of the coal body at the position closest to the working face when the same key layer is broken and obtained by a physical simulation test and field actual measurement0Remember ki=σ0σ (/ is the key layer level), and kiTake the average value, mark as ki′。
S1000-when the next working face is mined, the same steps are adopted to lay a physical model, and the stress of the advanced coal body is sigma' when the key layer is broken is monitored and obtained, and the stress is recorded as sigma = ki'Sigma' to increase the compression strength of the coal bodyR′And comparing the relative ratio, and judging the breaking impact strength of the key layer.
Claims (3)
1. A method for predicting breaking impact strength of key layers at different layers is characterized by comprising the following steps: comprises the following steps of (a) carrying out,
s100, before mining on the underground working face of the mine, vertically drilling a borehole television observation hole downwards from the earth surface along the advancing direction of the working face, observing the overlying strata structure and lithology of the working face through a borehole television, measuring, calculating and recording the thickness, the occurrence and the lithology of each coal-rock layer;
s200, randomly taking a coal rock core of one of the borehole television observation holes to test the mechanical property of the coal rock stratum, measuring and calculating the compressive strength, the tensile strength, the compressive strength, the volume weight, the thickness, the elastic modulus and the Poisson ratio of the coal rock stratum, and calculating to obtain the key layer position of the overlying rock stratum of the working surface through a key layer theory according to the measured mechanical parameters of the coal rock stratum;
s300, manufacturing a physical similar model (1), setting a similar proportion, calculating according to the similar proportion to obtain a matching number for manufacturing each coal rock layer, matching manufacturing materials according to the matching number, and paving a model;
s400, when the model (1) is laid, the coal seam (2) and the direct roof (3) are separated by a distanceDLaying a strain gauge (4), loading strength P on the strain gauge before laying the strain gauge, measuring strain change epsilon of the strain gauge, and measuring and calculating the elastic modulus of the strain gauge according to the formula E = P/epsilonE;
S500-set the width on both sides of the model asLAccording to the similar proportion, the excavation speed of the model (1) is calculated and obtained by the protective coal pillar (5)vAnd excavating the model working face (6) at the speed;
s600, mining along with the model working face (6), recording the data change of the working face advanced strain gauge (4) when the key layer (7) covering different layers is broken, and combining the elastic modulus of the strain gauge (4)ECalculating to obtain the advanced stress data sigma of the working surface (6);
s700-taking the leading stress sigma nearest to the working surface (6) and the compressive strength of the coal bodyRComparing:
if sigma is more than or equal to 2RThe breaking impact strength of the key layer is considered to be extremely high;
if it isR≤ σ <2RThe breaking impact strength of the key layer is considered to be higher;
if 0.5R≤σ<RThe breaking impact strength of the key layer is considered to be general;
if σ is less than 0.5RThe breaking impact strength of the key layer is considered to be weaker;
s800, after the working face is mined on the spot, stress measuring points are arranged at intervals in the coal seam in the advanced roadway range of the working face, and stress data sigma of the measuring points when different key layers of the overburden rock are broken is monitored0;
S900, sequentially comparing the stress sigma and the stress sigma of the coal body at the position closest to the working face when the same key layer is broken and obtained by a physical simulation test and field actual measurement0Remember ki=σ0σ, where i is the key layer horizon, and kiTake the average value, mark as ki′;
S1000-when the next working face is mined, the same steps are adopted for pavingSetting a physical model, monitoring to obtain the stress of the advanced coal body as sigma' when the key layer is broken, and recording the stress of sigma = ki'Sigma' to increase the compression strength of the coal bodyRAnd comparing the relative ratio, and judging the breaking impact strength of the key layer.
2. The method for predicting the breaking impact strength of the key layers at different horizons according to claim 1, wherein the method comprises the following steps: distance between strain gauges during layingDAnd face mining speed in the modelvThe relationship of (1) is D = (0.5 to 0.8)v。
3. The method for predicting the breaking impact strength of the key layers at different horizons according to claim 1, wherein the method comprises the following steps: the two sides of the model are reserved with a width ofLThe relationship between the protective coal pillar and the model laying length is L = (0.1-0.2) × the model laying length.
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